PC456L0NIP PC456L0NIP absolute maximum ratings outline dimensions (unit : mm) *1 when ambient temperature goes above 70 c, the power dissipation goes down at 0.45ma/ c. *2 when ambient temperature goes above 70 c, the power dissipation goes down at 0.8mw/ c. *3 when ambient temperature goes above 70 c, the power dissipation goes down at 1.8mw/ c. *4 40 to 60%rh, ac for 1minute *5 for 10s parameter symbol rating unit forward current i f 25 ma ma reverse voltage input output v r 5v v power dissipation p 45 output current supply voltage output voltage power dissipation 100 15 mw mw v o p o i o v v cc v iso (rms) kv operating temperature t opr ? 40 to + 125 ? 40 to + 100 ? 0.5 to + 35 ? 0.5 to + 35 c c storage temperature isolation voltage t stg *4 *3 *2 *1 *5 soldering temperature t sol 270 3.75 c (t a = 25 c) 1. programmable controller 2. inverter features applications high speed and high cmr ? opic photocoupler 1. high resistance to noise (cmr:min. 15kv/ s) 2. high speed response (t phl :max.400ns, t plh :max.550ns) 3. mini-flat package 4. isolation voltage (v iso (rms) :3.75kv) 5. recognized by ul, file no. e64380 (model no. pc456l) internal connection diagram anode mark pc456l anode cathode 6? gnd v o v cc 0.2 0.05 5.3 0.3 0.4 0.1 2.6 0.2 4.4 0.2 0.1 0.1 1.27 0.25 3.6 0.3 7.0 + 0.2 ? 0.7 0.5 + 0.4 ? 0.2 3 1 1 3 4 5 6 4 6 5 ? ?pic?optical ic) is a trademark of the sharp corporation. an opic consists of a light-detecting element and signal- processing circuit integrated onto a single chip. amp. 6 5 4 1 3 voltage regulator ? vde (vde0884) approved type is also available as an option notice in the absence of confirmation by device specification sheets, sharp takes no responsibility for any defects that may occ ur in equipment using any sharp devices shown in catalogs, data books, etc. contact sharp in order to obtain the latest device specification sheets before usin g any sharp device. internet internet address for electronic components group http://sharp-world.com/ecg/
PC456L0NIP electro-optical characteristics *6 parameter symbol unit input v a operating supply voltage low level output current high level supply current t a = 25 ? c, v r = 0, f = 1mhz pf output v ol v cc i ol high level output current i oh i cch low level supply current i ccl ma ma transfer characteristics "high low" threshold input current isolation resistance floating capacitance i fhl r iso c f ma ? pf t plh ns t phl ns propagation delay difference between any two parts ? tw ns distortion of pulse width t psk ns instantaneous common mode rejection voltage "output : high level" t a = 25 ? c, i f = 0, v cc = 15v, c l = 100pf, v cm = 1.5kv (p-p) , r l = 20k ? , v o > 3.0v t a = 25 ? c, i f = 10ma, v cc = 15v, c l = 100pf, v cm = 1.5kv (p-p) , r l = 20k ? , v o < 1.0v kv/ s instantaneous common mode rejection voltage "output : low level" cm l kv/ s t a = 25 ? c, i f = 10ma t a = 25 ? c, v r = 5v min. ? ? ? 5 10 10 ? 30 270 ? ? 150 ? ? ? 15 ? 15 max. 10 250 1.3 1.3 5 ? 1 450 450 ? ? 1.95 400 550 conditions "low high" propagation time "high low" propagation time *8 *8 *7 *9 *9 response time cmr cm h ? i f = 10ma, v o = 0.6v i f = 0, v cc = v o i f = 10ma, i o = 2.4ma i f = 0, v o = open i f = 10ma, v o = open v o = 0.8v, r l = 20k ? , v cc = 15v t a = 25 ? c, dc500v, 40 to 60%rh t a = 25 ? c, v = 0, f = 1mhz i f = 10ma (t phl ), i f = 0 (t plh ), v cc = 15v, r l = 20k ? , c l = 100pf v thlh = 2.0v, v thhl = 1.5v typ. ? v 4.5 35 ? 60 v ? 0.6 0.3 0.6 ma 4.4 ? 9 a ? 50 5 0.8 1.5 10 11 0.6 190 200 1.6 210 400 30 ? 30 (unless otherwise specified t a =? 40 to 100 c, v cc =4.5 to 35v) low level output voltage forward voltage reverse current terminal capacitance v f i r c t *6 it shall connect a by-pass capacitor of 0.01 f or more between v cc (pin 6 ) and gnd (pin 4 ) near the device, when it measures the transfer characteristics and the output side characteristics *7 distortion of pulse width ? tw = | t phl ? t plh | *8 refer to fig.1 *9 refer to fig.2 recommended operating conditions parameter symbol min. max. unit forward current output voltage operating temperature ma v supply voltage i f v o v cc t opr c 10 4.5 ? 40 0 20 35 100 35 v
PC456L0NIP power dissipation p, p o (mw) ambient temperature t a ( c) 0 20 40 45 60 80 100 ? 40 0 25 50 100 125 70 ? 25 p p o fig.3 forward current vs. ambient temperature fig.4 power dissipation vs. ambient temperature forward current i f (ma) ambient temperature t a ( c) 0 5 10 15 20 25 ? 40 0 25 50 100 125 70 ? 25 t phl t plh t f 90% 10% i f 20k ? gnd c l 0.1 f v ol v thlh v thhl 10ma 0ma i f v o v o 15v 47 ? amp. voltage regulator t r fig.1 test circuit for t phl and t plh fig.2 test circuit for cm h and cm l 20k ? c l gnd 0.1 f i f v o 15v a b amp. voltage regulator 1.5kv 0v v cm cm h ,v o cm l ,v o (i f = 0ma) (i f = 10ma) sw is a sw is b v cc v o (min.) v o (max.) v ol v cm +?
PC456L0NIP output current i o (ma) 0 15 10 5 05 15 10 20 forward current i f (ma) v o = 0.6v t a =? 40 ? c t a = 25 ? c t a = 100 ? c fig.5 output current vs. forward current forward voltage v f (v) forward current i f (ma) 1 10 100 0.1 1.00 1.20 1.40 1.60 1.80 2.00 t a = 75 ? c t a = 50 ? c t a = 25 ? c t a = 0 ? c t a = 100 ? c t a =? 20 ? c t a =? 40 ? c fig.6 forward current vs. forward voltage relative output current i o (%) 60 120 70 100 110 80 90 ? 40 0 ? 20 60 80 40 20 100 ambient temperature t a ( ? c) i f = 10ma v o = 0.6v i o = 100% at t a = 25 ? c threshold input current i fhl (ma) 0.0 5.0 2.0 3.0 4.0 ? 40 0 ? 20 60 80 40 20 100 ambient temperature t a ( ? c) v cc = 15v v o = 0.8v r l = 20k ? 1.0 fig.7 relative output current vs. ambient temperature fig.8 threshold input current vs. ambient temperature supply current i cch , i ccl (ma) 0.0 1.6 0.6 0.4 0.2 1.2 1.4 0.8 1.0 ? 40 0 ? 20 60 80 40 20 100 ambient temperature t a ( ? c) v cc = 35v v o = open i cch :i f = 0ma i ccl :i f = 10ma i ccl i cch fig.10 supply current vs. ambient temperature low level output voltage v ol (v) 0.0 0.6 0.3 0.4 0.5 ? 40 0 ? 20 60 80 40 20 100 ambient temperature t a ( ? c) v cc = 4.5v i f = 10ma i o = 2.4ma 0.2 0.1 fig.9 low level output voltage vs. ambient temperature
PC456L0NIP propagation delay time t phl , t plh ( s) 0 2.0 0.2 0.4 1.8 0.6 0.8 1.0 1.2 1.4 1.6 ? 40 0 ? 20 60 80 40 20 100 ambient temperature t a ( ? c) i f = 10ma v cc = 15v c l = 100pf r l = 20k ? t plh t phl fig.11 propagation delay time vs. ambient temperature propagation delay time t phl , t plh ( s) 0 2.0 0.2 0.4 1.8 0.6 0.8 1.0 1.2 1.4 1.6 0 5 10 15 20 25 30 35 40 45 50 load resistance r l (k ? ) i f = 10ma v cc = 15v c l = 100pf t plh t phl fig.12 propagation delay time vs. load resistance propagation delay time t phl , t plh ( s) 0 2.0 0.2 0.4 1.8 0.6 0.8 1.0 1.2 1.4 1.6 0 100 50 300 350 400 450 250 200 150 500 load capacitance c l (pf) i f = 10ma v cc = 15v r l = 20k ? t plh t phl propagation delay time t phl , t plh ( s) 0 2.0 0.2 0.4 1.8 0.6 0.8 1.0 1.2 1.4 1.6 010 52530 20 15 35 supply voltage v cc (v) i f = 10ma c l = 100pf r l = 20k ? t plh t phl fig.13 propagation delay time vs. load capacitance fig.14 propagation delay time vs. supply voltage propagation delay time t phl , t plh ( s) 0 2.0 0.2 0.4 1.8 0.6 0.8 1.0 1.2 1.4 1.6 04 2101618 14 12 8 620 forward current i f (ma) t plh t phl v cc = 15v c l = 100pf r l = 20k ? fig.15 propagation delay time vs. forward current
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